Deciphering the Isotopic Imprint of Nitrate to Reveal Nitrogen Source and Transport Mechanisms in a Tile-Drained Agroecosystem

IF 3.7 3区 环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES
Yinchao Hu, Zhongjie Yu, Wendy H. Yang, Andrew J. Margenot, Lowell E. Gentry, Michelle M. Wander, Richard L. Mulvaney, Corey A. Mitchell, Carlos E. Guacho
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Abstract

Installation of subsurface drainage systems has profoundly altered the nitrogen cycle in agricultural regions across the globe, facilitating substantial loss of nitrate (NO3) to surface water systems. Lack of understanding of the sources and processes controlling NO3 loss from tile-drained agroecosystems hinders the development of management strategies aimed at reducing this loss. The natural abundance nitrogen and oxygen isotopes of NO3 provide a valuable tool for differentiating nitrogen sources and tracking the biogeochemical transformations acting on NO3. This study combined multi-years of tile drainage measurements with NO3 isotopic analysis to examine NO3 source and transport mechanisms in a tile-drained corn-soybean field. The tile drainage NO3 isotope data were supplemented by characterization of the nitrogen isotopic composition of potential NO3 sources (fertilizer, soil nitrogen, and crop biomass) in the field and the oxygen isotopic composition of NO3 produced by nitrification in soil incubations. The results show that NO3 isotopes in tile drainage were highly responsive to tile discharge variation and fertilizer input. After accounting for isotopic fractionations during nitrification and denitrification, the isotopic signature of tile drainage NO3 was temporally stable and similar to those of fertilizer and soybean residue during unfertilized periods. This temporal invariance in NO3 isotopic signature indicates a nitrogen legacy effect, possibly resulting from N recycling at the soil microsite scale and a large water storage for NO3 mixing. Collectively, these results demonstrate how combining field NO3 isotope data with knowledge of isotopic fractionations can reveal mechanisms controlling NO3 cycling and transport under complex field conditions.

解密硝酸盐的同位素印记,揭示瓦片排水农业生态系统中的氮源和传输机制
地表下排水系统的安装极大地改变了全球农业地区的氮循环,使硝酸盐(NO3-)大量流失到地表水系统中。对控制瓦片排水农业生态系统中 NO3- 流失的来源和过程缺乏了解,这阻碍了旨在减少 NO3- 流失的管理策略的制定。NO3- 的天然丰度氮和氧同位素为区分氮源和跟踪 NO3- 的生物地球化学转化提供了宝贵的工具。这项研究将多年的瓦片排水测量与 NO3- 同位素分析相结合,研究了瓦片排水玉米-大豆田中 NO3- 的来源和迁移机制。除了瓦片排水 NO3- 同位素数据外,还对田间潜在 NO3- 源(化肥、土壤氮和作物生物量)的氮同位素组成以及土壤培养中硝化产生的 NO3- 的氧同位素组成进行了分析。结果表明,瓦片排水中的 NO3- 同位素对瓦片排水量变化和化肥投入量的反应非常灵敏。考虑到硝化和反硝化过程中的同位素分馏,瓦片排水中 NO3- 的同位素特征在时间上是稳定的,与未施肥期间化肥和大豆残留物的同位素特征相似。NO3- 同位素特征的这种时间不变性表明存在氮遗留效应,这可能是由于氮在土壤微观尺度上的循环以及 NO3- 混合的大量储水造成的。总之,这些结果表明,将野外 NO3-同位素数据与同位素分馏知识相结合,可以揭示在复杂的野外条件下控制 NO3-循环和迁移的机制。
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来源期刊
Journal of Geophysical Research: Biogeosciences
Journal of Geophysical Research: Biogeosciences Earth and Planetary Sciences-Paleontology
CiteScore
6.60
自引率
5.40%
发文量
242
期刊介绍: JGR-Biogeosciences focuses on biogeosciences of the Earth system in the past, present, and future and the extension of this research to planetary studies. The emerging field of biogeosciences spans the intellectual interface between biology and the geosciences and attempts to understand the functions of the Earth system across multiple spatial and temporal scales. Studies in biogeosciences may use multiple lines of evidence drawn from diverse fields to gain a holistic understanding of terrestrial, freshwater, and marine ecosystems and extreme environments. Specific topics within the scope of the section include process-based theoretical, experimental, and field studies of biogeochemistry, biogeophysics, atmosphere-, land-, and ocean-ecosystem interactions, biomineralization, life in extreme environments, astrobiology, microbial processes, geomicrobiology, and evolutionary geobiology
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